过表达VHA-c3基因拟南芥对黑暗、ABA与糖的响应

为研究液泡H+-ATPase c亚基基因(VHA-c3)在植物生长发育及非生物胁迫应答过程中的作用,构建了VHA-c3过表达载体转化拟南芥,获得过表达VHA-c3的转基因纯合体植株,采用半定量RT-PCR技术分析了转基因拟南芥中VHA-c3的表达量,然后对转基因拟南芥进行暗培养、ABA和糖处理。结果获得6个T2代株系转基因纯合体株系,其m RNA表达量均高于对照;黑暗条件下,5个VHA-c3转基因株系的根长变短;在正常光照下,3个转基因株系主根伸长和子叶的展开以及5个转基因株系的种子萌发对ABA的抑制不敏感;分别有5个和6个转基因株系的种子萌发对葡萄糖和蔗糖的抑制不敏感。推测VHA-c3可能影响根细胞的扩展,并可能参与ABA和糖介导的信号转导途径。     

过表达VHA-c1基因对拟南芥根长及ABA与糖响应的影响

为初步探讨液泡H+-ATPase c亚基基因(VHA-c1)在植物生长发育及信号转导中的作用,该实验构建了拟南芥VHA-c1的过表达载体,转化并获得转基因拟南芥纯合株系,通过半定量RT-PCR技术分析了VHA-c1的表达量,然后对其进行暗培养、ABA和糖处理。结果显示:(1)该实验获得7个T2代转基因纯系,其mRNA表达水平均高于野生型,表明过表达载体的构建是有效的。(2)黑暗条件下,6个拟南芥VHA-c1过表达纯合株系的根长变短。(3)光照条件下,4个转基因株系主根伸长和子叶的展开以及7个转基因株系的种子萌发对ABA的抑制不敏感。(4)分别有5个和4个转基因株系的种子萌发对葡萄糖和蔗糖的抑制不敏感。推测VHA-c1可能参与了ABA和糖介导的信号转导途径,并可能影响了拟南芥根细胞的扩展。     

VHA-c2&c4双基因沉默株系拟南芥对NaCl与ABA的响应

研究液泡H~+-ATPase c亚基基因(VHA-c2和VHA-c4)在植物生长发育及响应非生物胁迫过程中的功能,构建拟南芥VHA-c2c4的RNAi表达载体,通过浸花法转化野生型拟南芥。利用卡那霉素筛选纯合体株系,进行半定量PCR鉴定,并对其进行NaCl和ABA胁迫处理。获得7个T_2代双沉默基因纯合体株系,其VHA-c2和VHA-c4的mRNA表达水平均低于野生型。挑选沉默效率较高的3个株系进行NaCl和ABA处理,在NaCl处理下,它们的主根相对伸长量和种子萌发率均小于对照,表明VHAc2c4沉默株系对NaCl胁迫作用敏感。ABA处理下,子叶的展开程度和主根相对伸长量均比对照高,表明VHA-c2c4沉默株系对ABA抑制作用不敏感。NMT试验表明ABA促进了双沉默基因纯合体株系的H+内流能力。推测VHA-c2和VHA-c4的转录水平影响了植物对盐胁迫和ABA介导的信号转导途径的响应。     

沉默VHA-c4基因对拟南芥根长和种子萌发的影响

为了研究植物液泡H+-ATPase c亚基VHA-c4基因在拟南芥响应非生物胁迫中的作用,本研究构建了拟南芥VHA-c4基因沉默载体,利用农杆菌介导,将线性化的沉默载体dsDNA片段整合在拟南芥基因组上,筛选获得了能够不同程度特异沉默VHA-c4基因的7个转基因株系c4-1～c4-7,并对VHA-c4基因沉默效果最好的株系c4-2进行NaCl、ABA、6%葡萄糖胁迫处理。结果显示:在特定浓度梯度的NaCl处理后,沉默株系c4-2的主根相对伸长量和种子萌发率都被明显抑制,并且被抑制效果远远高于野生型株系。然而,在特定浓度梯度的ABA和葡糖糖处理后,沉默株系c4-2的主根相对伸长量和种子的萌发率虽然也都有一定程度的抑制,但是其被抑制效果远远低于野生型拟南芥。结果显示沉默了VHA-c4基因后,显著降低了拟南芥对NaCl的耐受性,影响了其的生长发育,然而对ABA和葡糖糖的抑制作用却表现为很不敏感,这可能是因为H~+-ATPase在盐胁迫信号通路和ABA信号通路中起着不同的(正负)调控功能。     

转CkLEA4基因拟南芥种子萌发期的抗逆性分析

该研究在实验室前期研究的基础上,将受脱水、盐胁迫和ABA诱导的柠条锦鸡儿CkLEA4基因转入野生型拟南芥,并利用实时荧光定量PCR从8株纯合体中筛选出3个表达量不同的株系,比较野生型和转CkLEA4基因过表达拟南芥种子在不同胁迫处理下的萌发率,以探讨CkLEA4基因在植物抵抗逆境胁迫中的功能。结果发现:(1)在不同浓度NaCl、甘露醇及ABA处理下,转CkLEA4基因过表达拟南芥种子的萌发率均高于野生型,随着NaCl、甘露醇及ABA浓度增加,各株系萌发率均降低,但野生型的萌发率下降幅度均高于3个过表达株系,并且在200mmol/L NaCl和400mmol/L甘露醇处理下,过表达株系子叶绿化率均显著高于野生型。(2)在低浓度ABA处理下,CkLEA4过表达植株子叶的绿化率也高于野生型。研究表明,柠条锦鸡儿CkLEA4基因提高了拟南芥种子萌发阶段对盐、ABA及渗透胁迫的耐受性。     

拟南芥VHA-c3启动子的GUS基因融合表达

VHA-c3基因是拟南芥液泡H+-ATPase c亚基的5个同源基因之一,已有研究结果表明其与植物抗非生物胁迫有关。本论文在克隆不同长度VHA-c3基因上游调控序列的基础上,利用GUS报告基因,研究了VHA-c3基因的植物组织及器官定位。结果表明：VHA-c3起始密码子上游772bp的序列内存在着VHA-c3基因的基本启动子元件,可指导基因组成型表达在拟南芥的叶片、表皮毛、叶柄、根、雄蕊、柱头和萼片;在VHA-c3起始密码子ATG上游2812bp-2234bp片段和1496bp-772bp片段中各存在一个负调控元件,在2234bp-1496bp片段中存在一个正调控元件,它们的存在可控制基因在气孔中的表达。     

拟南芥GH3.9基因的过表达及其表型分析

为研究GH3.9基因在植物生长发育过程中的作用,利用RT-PCR成功克隆到GH3.9基因,该基因全长为1 750bp。通过构建pEGAD-GH3.9过表达载体转化拟南芥,获得过表达GH3.9基因纯系转基因株系GH3.9ox-3和GH3.9ox-7。对拟南芥野生型(WT)和转基因株系(GH3.9ox-3和GH3.9ox-7)幼苗用不同光强和光质进行处理,结果显示:在蓝光、红光、远红光等不同光照强度下培养,过表达株系幼苗下胚轴的生长均明显受到抑制,且较野生型明显;采用不同光周期处理拟南芥幼苗,过表达幼苗下胚轴的伸长明显低于野生型;对成年植株表型进行观察,发现过表达株系植株矮小、雄蕊变短、果荚短小。研究表明:GH3.9基因参与了拟南芥生长发育调控,过表达GH3.9基因对拟南芥生长有抑制作用。     

AtNHX5基因过量表达对拟南芥耐盐性的影响

为了研究AtNHX5基因在植物耐盐中的作用,构建了植物过量表达载体pROKⅡ-AtNHX5,并转化拟南芥。结果显示:(1)RT-PCR检测表明,转基因拟南芥中AtNHX5基因的表达大幅提高。(2)对转基因纯合株系进行耐盐性分析显示,AtNHX5过量表达提高了植株在种子萌发和苗期的耐盐性。(3)转基因植株在盐处理下的干重、鲜重以及地上部分Na+、K+含量均高于野生型对照。在200mmol/L NaCl处理下,以转基因株系a1-4为例,其地上部分单株鲜重、单株干重、K+含量分别是野生型的1.27、1.54、1.16倍,较野生型显著升高。研究表明,过量表达AtNHX5基因促进了盐胁迫下转基因植株对K+的吸收,转基因拟南芥的耐盐性明显提高。     

蔗糖合酶基因AtSUS3干涉后对拟南芥角果发育的影响

蔗糖合酶(SuSy)是植物蔗糖代谢关键酶之一,该研究利用反向遗传学手段,采用RNAi技术抑制拟南芥中AtSUS3基因的表达,测定纯系转基因植株的抽苔率,并对酶活性、糖含量等指标以及糖代谢相关基因的表达进行了检测,探讨SuSy在植物发育中的作用。结果显示:(1)转基因拟南芥的抽苔平均早于野生型植株2～3d,且优先3～4d完成抽苔。(2)开花后生长天数对角果蔗糖和葡萄糖含量有显著影响,而对果糖含量影响不显著;开花后5d时,野生型株系的葡萄糖含量显著高于转基因株系SUS3-2,至15d时,两种转基因株系葡萄糖含量均显著低于野生型株系。(3)开花后生长天数对SuSy、SPS、INV的活性均有显著影响,随开花时间延长,野生型株系SuSy活性显著低于转基因株系,而SPS和INV则相反。(4)AtSUS3基因沉默对其他糖代谢基因有不同程度的影响,开花后5d时,转基因植株的角果中AtCesA1、AtCesA7和AtCINV1的表达量较野生型都有所增加;开花后15d时,转基因植株的角果中AtCesA1、AtCesA7的表达量较野生型高,而AtCINV、AtCwINV的表达量比野生型低。研究表明,拟南芥AtSUS3基因沉默后,在正常生长条件下未造成植株发育异常,同时还可能通过同源家族中其他SuSy的表达水平增加,促进了该酶及糖代谢相关基因整体水平的增加,有助于角果成熟。     

拟南芥钙调素结合蛋白参与胁迫响应的研究

采用实时荧光定量RT-PCR和Northern blotting技术检测了野生型拟南芥中CBP60g基因对丁香假单胞菌和非生物胁迫的响应,并对丁香假单胞菌接种后,野生型拟南芥、cbp60g-1突变体和CBP60g过表达转基因植物中抗逆相关基因的表达变化进行检测。结果显示:(1)在野生型拟南芥中CBP60g基因的表达能被丁香假单胞菌、高盐、冷和机械损伤所诱导。(2)经丁香假单胞菌诱导后病程相关基因PR5和AIG1的表达在过表达转基因植物中明显高于野生型。(3)受干旱和ABA诱导的AtMYB2基因的表达在过表达转基因植物中也高于野生型。研究表明,CBP60g同时参与了拟南芥对生物和非生物胁迫响应。     

35S::GmPM30在拟南芥的根系生长中表现为对ABA的敏感性降低(英文)

LEA protein,late-embryogenesis-abundant protein,is importantin response to thesalt and drought stresses in plants.Here,weidentified a cDNA full length of LEA from soybean and found that LEA enhance the ability of anti-salinity in transgenic Arabidopsis thaliana.The expression of GmPM30 increases highly under salinity,cold or ABA treatment,and enhances by certain degree under drought stress.The germination rates,primary root lengths and survival rate of GmPM30 over-expression lines are obviously higher than that of the wild-type after suffering the salinity stress.Our studies displays that GmPM30-ox apparently enhances the tolerance to salinity in Arabidopsis thaliana.     

Ectopic expression of ABSCISIC ACID 2/GLUCOSE INSENSITIVE 1 in Arabidopsis promotes seed dormancy and stress tolerance

Abscisic acid (ABA) is an important phytohormone that plays a critical role in seed development, dormancy, and stress tolerance. 9-cis-Epoxycarotenoid dioxygenase is the key enzyme controlling ABA biosynthesis and stress tolerance. In this study, we investigated the effect of ectopic expression of another ABA biosynthesis gene, ABA2 (or GLUCOSE INSENSITIVE 1 [GIN1]) encoding a short-chain dehydrogenase/reductase in Arabidopsis (Arabidopsis thaliana). We show that ABA2-overexpressing transgenic plants with elevated ABA levels exhibited seed germination delay and more tolerance to salinity than wild type when grown on agar plates and/or in soil. However, the germination delay was abolished in transgenic plants showing ABA levels over 2-fold higher than that of wild type grown on 250 mm NaCl. The data suggest that there are distinct mechanisms underlying ABA-mediated inhibition of seed germination under diverse stress. The ABA-deficient mutant aba2, with a shorter primary root, can be restored to normal root growth by exogenous application of ABA, whereas transgenic plants overexpressing ABA2 showed normal root growth. The data reflect that the basal levels of ABA are essential for maintaining normal primary root elongation. Furthermore, analysis of ABA2 promoter activity with ABA2::beta-glucuronidase transgenic plants revealed that the promoter activity was enhanced by multiple prolonged stresses, such as drought, salinity, cold, and flooding, but not by short-term stress treatments. Coincidently, prolonged drought stress treatment led to the up-regulation of ABA biosynthetic and sugar-related genes. Thus, the data support ABA2 as a late expression gene that might have a fine-tuning function in mediating ABA biosynthesis through primary metabolic changes in response to stress.     

油菜素内酯合成酶基因DAS5促进杨树生长及提高抗旱性的作用

以河北杨(Populus hopeiensis)为材料, 研究拟南芥(Arabidopsis thaliana)油菜素内酯(BR)生物合成酶基因DAS5对其生长表型、生物量及抗旱性的影响。结果表明: (1) 转DAS5基因河北杨植株的根长、地径、叶柄及叶片长度均显著大于野生型植株, 且地上、地下部分干重及根冠比显著高于野生型, 其拥有发达的根系; (2) 在干旱胁迫下, 转DAS5基因河北杨植株失水褪绿速度较野生型植株缓慢, 在复水后转基因植株能够较早较好地恢复活力, 萌发较多的新幼芽且长势良好; (3)控水期间, 转基因河北杨的相对生长率显著高于野生型, 且随着干旱胁迫程度的加剧, 其可溶性糖含量、游离脯氨酸含量、过氧化氢酶(CAT)活性、超氧化物歧化酶(SOD)活性均显著高于野生型。实验结果表明, 与野生型相比, 转基因植株具有较高的生长量与较强的抗干旱胁迫能力, 说明来自拟南芥的BR生物合成酶基因DAS5可以显著增加河北杨的生长量并在抵御干旱胁迫机制中发挥重要作用。     

高粱ATP合成酶E亚基基因(SbATPase-E)的克隆及其抗逆功能研究

高粱是一种抗旱性较强的禾谷类作物。本研究在高粱中克隆到一个全长为693 bp的编码ATP合成酶E亚基的基因(SbATPase-E)。在高粱幼苗期,SbATPase-E基因受Na Cl和脱落酸(ABA)处理诱导上调表达。该基因在拟南芥中过量表达可提高转基因植株的耐旱性和耐盐性,在逆境胁迫条件下转基因拟南芥植株较野生型植株根系发达,可能是转基因植株耐旱性和耐盐性提高的主要原因。在干旱胁迫条件下,转基因植株中DREB2A、P5CS1、RD29A、RAB18和ABI1基因的表达量相对于野生型植株中的表达量提高更为显著;在高盐处理条件下,转基因植株中SOS1和SOS2基因的表达量也较野生型植株中的表达量明显提高。这些抗逆相关基因的上调表达可能是转基因植株抗逆性提高的主要分子机制。     

小拟南芥ApZFP基因异源超表达促进拟南芥开花并提高耐逆性

锌指蛋白(ZFP)是一类重要的转录因子, 广泛参与植物的生长发育和非生物胁迫应答。新疆小拟南芥(Arabidopsispumila)又名无苞芥, 是十字花科短命植物, 具有高光效、繁殖力强和适应干旱等生物学特征, 而且比模式植物拟南芥(A.thaliana)更耐高盐胁迫。将前期克隆的小拟南芥锌指蛋白基因ApZFP通过花滴法转化到哥伦比亚生态型拟南芥(Col-0)中,获得了独立表达的转基因株系。表型观察发现, 过量表达ApZFP基因可促使拟南芥在长短日照下均提前开花。实时荧光定量PCR结果显示, 转基因拟南芥株系中, 光周期途径中的CO基因和年龄途径中的SPL基因表达上调; 春化、环境温度和自主途径中的FLC基因表达下调; 编码成花素的基因FT及下游开花相关基因AP1和LFY的表达量均升高。进一步通过盐、干旱和ABA胁迫处理ApZFP转基因株系的种子和幼苗, 发现在胁迫处理下, 与对照相比, 转基因拟南芥种子萌发率较高, 幼苗主根较长。因此推测, ApZFP在植物发育过程中具有多种功能, 可能既参与植物的开花转变过程, 又同其它植物的锌指蛋白基因一样, 参与植物的耐逆过程。     

Expression of the algal cytochrome c6 gene in Arabidopsis enhances photosynthesis and growth

Photosynthetic plants convert light energy into ATP and NADPH in photosynthetic electron transfer and photophosphorylation, and synthesize mainly carbohydrates in the Calvin-Benson cycle. Here we report the enhancement of photosynthesis and growth of plants by introducing the gene of an algal cytochrome c6, which has been evolutionarily eliminated from higher plant chloroplasts, into the model plant Arabidopsis thaliana. At 60 d after planting, the plant height, leaf length and root length of the transformants were 1.3-, 1.1- and 1.3-fold those in the wild-type plants, respectively. At the same time, in the transgenic plants, the amounts of chlorophyll, protein, ATP, NADPH and starch were 1.2-, 1.1-, 1.9-, 1.4- and 1.2-fold those in the wild-type plants, respectively. The CO2 assimilation capacity of the transgenic plants was 1.3-fold that of the wild type. Moreover, in transgenic Arabidopsis expressing algal cytochrome c6, the 1-qP, which reflects the reduced state of the plastoquinone pool, is 30% decreased compared with the wild type. These results show that the electron transfer of photosynthesis of Arabidopsis would be accelerated by the expression of algal cytochrome c6. Our results demonstrate that the growth and photosynthesis of Arabidopsis plants could be enhanced by the expression of the algal cytochrome c6 gene.     

A zinc finger-containing glycine-rich RNA-binding protein, atRZ-1a, has a negative impact on seed germination and seedling growth of Arabidopsis thaliana under salt or drought stress conditions

Despite the fact that glycine-rich RNA-binding proteins (GRPs) have been implicated in the responses of plants to changing environmental conditions, the reports demonstrating their biological roles are severely limited. Here, we examined the functional roles of a zinc finger-containing GRP, designated atRZ-1a, in Arabidopsis thaliana under drought or salt stress conditions. Transgenic Arabidopsis plants overexpressing atRZ-1a displayed retarded germination and seedling growth compared with the wild-type plants under salt or dehydration stress conditions. In contrast, the loss-of-function mutants of atRZ-1a germinated earlier and grew faster than the wild-type plants under the same stress conditions. Germination of the transgenic plants and mutant lines was influenced by the addition of ABA or glucose, implying that atRZ-1a affects germination in an ABA-dependent way. H(2)O(2) was accumulated at higher levels in the transgenic plants compared with the wild-type plants under stress conditions. The expression of several germination-responsive genes was modulated by atRZ-1a, and proteome analysis revealed that the expression of different classes of genes, including those involved in reactive oxygen species homeostasis and functions, was affected by atRZ-1a under dehydration or salt stress conditions. Taken together, these results suggest that atRZ-1a has a negative impact on seed germination and seedling growth of Arabidopsis under salt or dehydration stress conditions, and imply that atRZ-1a exerts its function by modulating the expression of several genes under stress conditions.